Your search keyword '"SPEED of sound"' showing total 2 results

1. Acoustic attenuation, phase and group velocities in liquid-filled pipes: Theory, experiment, and examples of water and mercury.

Author

Baik, Kyungmin, Jian Jiang, and Leighton, Timothy G.

Subjects

*STEEL pipe, *SPEED of sound, *ULTRASONIC wave attenuation, *TUBES, *MERCURY

Abstract

Del Grosso's [Acustica 24, 299-311 (1971)] formulation, which predicts the phase speed of propagating axisymmetric modes inside a liquid-filled tube, is here extended to the complex domain in order to predict the attenuation, as well as the sound speed, of the modes as a function of frequency. Measurements of the sound speeds and the attenuations of the modes were performed in a water-filled Poly (methyl methacrylate) (PMMA) tube of internal radius, b=4.445 cm, in the range of the wavenumber-radius product, k1b, from 2 to 10. Parts of three or four modes were investigated and the measured sound speeds and the damping of the modes were compared with the theoretical predictions. The theory was then used to estimate the modal sound speeds and attenuations in a stainless-steel pipe filled with mercury having the same dimensions as are used in the Spallation Neutron Source at Oak Ridge National Laboratory, Tennessee. [ABSTRACT FROM AUTHOR]

Published

2010

2. Theoretical Investigation of Phase Velocity, Group Velocity and Attenuation of Acoustic Waves in a Liquid-Filled Cylinder.

Author

Baik, K., Jiang, J., and Leighton, T. G.

Subjects

SPEED of sound, ATTENUATION (Physics), ACOUSTIC emission, RADIO frequency modulation, STAINLESS steel, NEUTRON sources

Abstract

Theoretical investigations are undertaken with the propagation of sound inside the tube filled with liquid. Previous theoretical works by Del Grosso's, Lafleur and Shields, and Elvira-Segura are here reviewed and extended to the complex domain in order to predict the attenuation, as well as the sound speed, of the modes as a function of frequency. Phase velocity, group velocity, the attenuation, and cut-off frequencies of modes are obtained for the water-filled PMMA (Perspex) tube of internal radius, b=4.445 cm, and thickness, h=0.5 cm in the range of the wavenumber-radius product, k1b , up to 18. The theory was then applied to the case of a stainless-steel pipe filled with mercury having the dimensions as used in the Spallation Neutron Source at Oak Ridge National Laboratory, Tennessee. [ABSTRACT FROM AUTHOR]

Published

2009